CN219497896U - Graphene battery heat dissipation mechanism - Google Patents

Abstract

The application discloses a graphene battery cooling mechanism relates to battery cooling technical field. The application includes the radiating box, install the graphene battery in the radiating box, the radiating box includes box and lower end box, go up the box with lower end box wall thickness is cavity and inside one side offered a plurality of radiating grooves rather than the wall thickness intercommunication, lower end box with go up be connected with the inside hollow bounding wall between the box, go up the box with the intercommunication has the mounting box between the end box down, install radiator fan in the mounting box, the mounting box with the intercommunication has the breather pipe between the bounding wall, the last air inlet groove of having seted up of bounding wall, install refrigeration subassembly in the bounding wall. The application enters into the radiating box through the air refrigeration of radiator fan cooperation refrigeration subassembly with outside to realize the cooling when charging to the graphene battery, can reduce the condition emergence of overheated influence graphene battery life when charging of graphene battery, structural design has the practicality.

Description

Graphene battery heat dissipation mechanism

Technical Field

The application relates to the technical field of battery heat dissipation, in particular to a graphene battery heat dissipation mechanism.

Background

The graphene battery is a new energy battery developed by utilizing the characteristic that lithium ions rapidly and largely shuttle between the surface of the graphene and an electrode, and a separator filled with electrolyte separates two electrode plates. The graphene battery is easy to overheat due to the fact that the temperature of the graphene battery is increased during discharging, the service life of the graphene battery is affected, the existing graphene battery mainly dissipates heat autonomously, and the heat dissipation effect is general.

Disclosure of Invention

The purpose of the present application is: to solve the problems set forth in the background above, the present application provides a graphene battery heat dissipation mechanism.

The application specifically adopts the following technical scheme for realizing the purposes:

the graphene battery cooling mechanism comprises a cooling box, a graphene battery is installed in the cooling box, the cooling box comprises an upper box and a lower box, a plurality of cooling grooves communicated with the wall thickness of the lower box are formed in one side of the hollow wall thickness of the lower box, the lower box and a surrounding plate which is hollow in the inner portion is connected between the upper box, an installation box is communicated between the upper box and the lower box, a cooling fan is installed in the installation box, a ventilation pipe is communicated between the installation box and the surrounding plate, an air inlet groove is formed in the surrounding plate, and a refrigerating assembly is installed in the surrounding plate.

Further, the refrigeration assembly comprises a radiating water pipe arranged on the coaming, the radiating water pipe comprises a radiating part and a cooling part, the radiating part is positioned outside the coaming and used for radiating water, and the cooling part is positioned inside the coaming.

Further, the cooling part is cooling pipes which are distributed in the coaming in a snake shape, and the cooling pipes are symmetrically distributed in the coaming.

Further, the radiating part is a radiating pipe with serpentine wiring, a connecting frame is constructed on the coaming, a semiconductor refrigerating sheet is arranged on the connecting frame, the refrigerating surface of the semiconductor refrigerating sheet is attached to the radiating pipe, two free ends of the radiating pipe are respectively communicated with two ends of the cooling pipe through connecting pipes, and a water pump is arranged on the connecting pipes.

Further, a heat discharging pipe is connected to one side of the coaming, a pipeline is communicated between one side of the heat discharging pipe and the connecting frame, the radiating surface of the semiconductor refrigerating sheet is located in the pipeline, and the notch of the air inlet groove is perpendicular to the free end of the heat discharging pipe.

Further, a frame plate is arranged in the heat discharging pipe, a rotary fan blade is rotatably arranged on the frame plate, and a driving part for driving the rotary fan blade to rotate is arranged on the heat dissipation box.

Further, the output shaft of the cooling fan passes through the mounting box to be located outside, the driving part comprises two rotating rods which are vertically and rotatably mounted on the cooling box, a first bevel gear assembly is mounted between one rotating rod and the rotating fan blades, a second bevel gear assembly is mounted between the other rotating rod and the output shaft of the cooling fan, and a synchronous belt assembly is mounted between the two rotating rods.

The beneficial effects of this application are as follows:

the application enters into the radiating box through the air refrigeration of radiator fan cooperation refrigeration subassembly with outside to realize the cooling when charging to the graphene battery, can reduce the condition emergence of overheated influence graphene battery life when charging of graphene battery, structural design has the practicality.

Drawings

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a schematic view of another view of FIG. 1 of the present application;

FIG. 3 is an exploded view of a portion of the construction of the present application;

FIG. 4 is an exploded view of yet another portion of the construction of the present application;

FIG. 5 is a partial perspective cross-sectional view of FIG. 1 of the present application;

FIG. 6 is a further partial perspective cross-sectional view of FIG. 1 of the present application;

reference numerals: 1. a heat dissipation box; 101. loading the box; 102. a lower bottom box; 103. a heat sink; 104. coaming plate; 105. a mounting box; 2. a heat radiation fan; 3. a vent pipe; 4. an air inlet groove; 5. a refrigeration assembly; 501. a heat dissipation water pipe; 5011. a heat dissipation part; 5012. a cooling part; 6. a connection frame; 7. a semiconductor refrigeration sheet; 8. a connecting pipe; 9. a heat discharging pipe; 10. a pipe; 11. a frame plate; 12. rotating the fan blades; 13. a driving section; 1301. a rotating rod; 1302. and a timing belt assembly.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

As shown in fig. 1-6, the graphene battery heat dissipation mechanism provided in one embodiment of the present application includes a heat dissipation box 1, a graphene battery is installed in the heat dissipation box 1, the heat dissipation box 1 includes an upper box 101 and a lower bottom box 102, the wall thickness of the upper box 101 and the wall thickness of the lower bottom box 102 are hollow, a plurality of heat dissipation grooves 103 communicated with the wall thickness are formed in one side of the upper box, a hollow enclosing plate 104 is connected between the lower bottom box 102 and the upper box 101, an installation box 105 is communicated between the upper box 101 and the lower bottom box 102, a heat dissipation fan 2 is installed in the installation box 105, a ventilation pipe 3 is communicated between the installation box 105 and the enclosing plate 104, an air inlet groove 4 is formed in the enclosing plate 104, a refrigeration component 5 is installed in the enclosing plate 104, the upper box 101 is in a frame shape and is covered with a box cover during charging, the radiator fan 2 rotates, outside air passes refrigeration subassembly 5 by radiator fan 4 bounding wall 104 in, the air that flows this moment, refrigerate the air by refrigeration subassembly 5, cold air can enter into in the breather pipe 3 this moment, bounding wall 104 communicates with installation box 105 through breather pipe 3, consequently, cold air enters into in the installation box 105, so cold air can enter into in last box 101 and the lower end box 102 in passing radiator fan 2, because a plurality of radiating grooves 103 have been seted up on last box 101 and the lower end box 102 medial surface, thereby make cold air pass in the radiating groove 103, cool down the graphene battery in the radiator box 1, reduce the overheated phenomenon that influences graphene battery life when charging, the practicality of structure.

As shown in fig. 3, in some embodiments, the refrigeration assembly 5 includes a heat dissipating water pipe 501 installed on the shroud 104, the heat dissipating water pipe 501 includes a heat dissipating portion 5011 and a cooling portion 5012, the heat dissipating portion 5011 is located outside the shroud 104 and is used for dissipating heat from a water body, the cooling portion 5012 is located inside the shroud 104, that is, after external air enters into the shroud 104, the external air passes through the cooling portion 5012 in the heat dissipating water pipe 501, so as to cool the external air, at this time, the temperature of the water in the heat dissipating water pipe 501 increases, and the water with the increased temperature continuously circulates in the heat dissipating water pipe 501, so that the water is cooled through the heat dissipating portion 5011, thereby reducing the temperature of the water in the heat dissipating water pipe 501, so as to realize continuous cooling of the air flowing in the shroud 104.

As shown in fig. 3, in some embodiments, the cooling portion 5012 is a cooling tube that is distributed in the coaming 104 in a serpentine manner, and the cooling tubes are distributed in the coaming 104 in a symmetrical manner, as shown in fig. 3, and the cooling tubes are distributed in a serpentine manner from top to bottom along with the length direction of the coaming 104, so that the heat dissipation area is increased, and preferably, the cooling tubes can be made of copper, so that the heat dissipation effect is further improved.

As shown in fig. 1 and 3, in some embodiments, the heat dissipation portion 5011 is a heat dissipation tube with serpentine wiring, the surrounding plate 104 is configured with a connection frame 6, the connection frame 6 is provided with a semiconductor refrigeration piece 7, the refrigeration surface of the semiconductor refrigeration piece 7 is attached to the heat dissipation tube, two free ends of the heat dissipation tube are respectively communicated with two ends of the heat dissipation tube through a connection tube 8, a water pump is installed on the connection tube 8, when the water pump is started, water in the heat dissipation water tube 501 continuously flows, when the water of the heat dissipation tube flows into the heat dissipation tube, heat dissipation to the heat dissipation tube is achieved through the semiconductor refrigeration piece 7, the serpentine distribution of the heat dissipation tube further improves the contact surface with the semiconductor refrigeration piece 7, and therefore the refrigerating effect of the water inside the heat dissipation water tube 501 is improved.

As shown in fig. 1, fig. 2 and fig. 4, in some embodiments, a heat discharging pipe 9 is connected to one side of a shroud 104, a pipeline 10 is connected between one side of the heat discharging pipe 9 and the connection frame 6, the heat dissipation surface of the semiconductor refrigeration piece 7 is located in the pipeline 10, the notch of the air inlet groove 4 is perpendicular to the free end of the heat discharging pipe 9, and the notch of the air inlet groove 4 is perpendicular to the free end of the pipeline 10, so that hot air emitted by the heat dissipation surface of the semiconductor refrigeration piece 7 is not easy to be sucked into the shroud 104 due to the suction force in the notch of the air inlet groove 4, and the heat dissipation effect of the graphene battery due to the hot air emitted by the heat dissipation surface is prevented.

As shown in fig. 5, in some embodiments, a frame plate 11 is installed in the heat exhaust pipe 9, a rotary fan blade 12 is rotatably installed on the frame plate 11, a driving part 13 for driving the rotary fan blade 12 to rotate is installed on the heat dissipation box 1, and the rotary fan is rotated by the driving part 13, so that heat emitted by a heat dissipation surface of the semiconductor refrigeration sheet 7 is far away from the air inlet groove 4, and the heat dissipation effect of the graphene battery is further prevented from being influenced by the heat of the heat dissipation surface.

As shown in fig. 5 and 6, in some embodiments, the output shaft of the cooling fan 2 is located outside through the mounting box 105, the driving part 13 includes two rotating rods 1301 vertically rotatably mounted on the cooling box 1, a first bevel gear assembly is mounted between one rotating rod 1301 and the rotating fan blade 12, a second bevel gear assembly is mounted between the other rotating rod 1301 and the output shaft of the cooling fan 2, a synchronous belt assembly 1302 is mounted between the two rotating rods 1301, the bevel gear assemblies are two bevel gears meshed with each other, the bevel gears are mounted on the rotating rods 1301, the other two corresponding bevel gears are mounted on the rotating fan blade 12 and the output shaft of the cooling fan 2, when the output shaft of the cooling fan 2 rotates, the corresponding rotating rods 1301 are rotated by the second bevel gear assembly, because the two rotating rods 1301 are connected by the synchronous belt assembly 1302, the two rotating rods 1301 are simultaneously rotated, the synchronous belt assembly 1302 is an existing belt pulley and a belt, the two belt pulleys are respectively mounted on the two rotating rods 1301, and the belt is synchronously connected to the two belt pulleys.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (7)

1. Graphene battery cooling mechanism, its characterized in that, including radiating box (1), install the graphene battery in radiating box (1), radiating box (1) include box (101) and lower end box (102), go up box (101) with lower end box (102) wall thickness is cavity and inside one side offered a plurality of radiating grooves (103) rather than wall thickness intercommunication, lower end box (102) with go up be connected with inside hollow bounding wall (104) between box (101), go up box (101) with communicate between box (102) down and have mounting box (105), install radiator fan (2) in mounting box (105), mounting box (105) with communicate between bounding wall (104) and have breather pipe (3), air inlet groove (4) have been offered on bounding wall (104), install refrigeration subassembly (5) in bounding wall (104).

2. The graphene battery heat dissipation mechanism according to claim 1, wherein the refrigeration assembly (5) comprises a heat dissipation water pipe (501) mounted on the coaming (104), the heat dissipation water pipe (501) comprises a heat dissipation portion (5011) and a cooling portion (5012), the heat dissipation portion (5011) is located outside the coaming (104) and is used for dissipating heat of a water body, and the cooling portion (5012) is located inside the coaming (104).

3. The graphene battery heat dissipation mechanism according to claim 2, wherein the cooling portion (5012) is a cooling tube which is distributed in the coaming (104) in a serpentine shape, and the cooling tube is symmetrically distributed in the coaming (104).

4. The graphene battery heat dissipation mechanism according to claim 3, wherein the heat dissipation portion (5011) is a heat dissipation tube with serpentine wiring, a connection frame (6) is configured on the surrounding plate (104), a semiconductor refrigeration piece (7) is mounted on the connection frame (6), a refrigeration surface of the semiconductor refrigeration piece (7) is attached to the heat dissipation tube, two free ends of the heat dissipation tube are respectively communicated with two ends of the heat dissipation tube through a connecting tube (8), and a water pump is mounted on the connecting tube (8).

5. The graphene battery heat dissipation mechanism according to claim 4, wherein a heat extraction pipe (9) is connected to one side of the coaming (104), a pipeline (10) is communicated between one side of the heat extraction pipe (9) and the connecting frame (6), a heat dissipation surface of the semiconductor refrigeration piece (7) is located in the pipeline (10), and a notch of the air inlet groove (4) is perpendicular to a free end of the heat extraction pipe (9).

6. The graphene battery heat dissipation mechanism according to claim 5, wherein a frame plate (11) is installed in the heat extraction pipe (9), a rotary fan blade (12) is rotatably installed on the frame plate (11), and a driving part (13) for driving the rotary fan blade (12) to rotate is installed on the heat dissipation box (1).

7. The graphene battery heat dissipation mechanism according to claim 6, wherein an output shaft of the heat dissipation fan (2) passes through the mounting box (105) to be located outside, the driving part (13) comprises two rotating rods (1301) vertically rotatably mounted on the heat dissipation box (1), a first bevel gear assembly is mounted between one rotating rod (1301) and the rotating fan blade (12), a second bevel gear assembly is mounted between the other rotating rod (1301) and the output shaft of the heat dissipation fan (2), and a synchronous belt assembly (1302) is mounted between the two rotating rods (1301).